BE1026183B1 - Resilient blades - Google Patents

Abstract

A cutting unit for cutting cardboard, comprising: - a cutting table with a first cutting edge, - a knife with a second cutting edge, - a first actuator, mounted between the cutting table and the knife, for moving the knife relative to the cutting table in an upward and downward cutting movement, wherein the first and the second cutting edge lie at an angle, so that a contact point can be identified between the first and the second cutting edge during the cutting movement, - a pressure element, provided to exert a force on the knife, to increase a pressure between the first cutting edge and the second cutting edge at the point of contact.

Description

BE2018 / 5233 Resilient blades

The invention relates to a cutting unit for cutting cardboard, and preferably to a cutting device for making blanks.

The importance of cutting cardboard quickly and efficiently is growing. Cardboard is used in many applications, including the making of boxes, whose production explodes. One reason for this is the growing sale of goods via the internet. It is also expected that the sale of goods via the internet will continue to rise for a while. A diverse range of goods with different sizes and shapes is offered online. When a purchase is made online, it can be the same or different goods for one or more. The goods are delivered via a parcel service or courier to a delivery address. For this purpose, the goods are typically packed together in one or more boxes, which are folded from blanks.

EP3231594 describes a rolling knife for cutting cardboard, using a rotatably driven cutting head. The cutting head is cylindrical, with a knife mounted in the longitudinal direction of the cylinder on the surface. The cutting head is attached to a first driven shaft. Similarly, the counter knife is also mounted on a cylindrical cutter head. This cutting head is then mounted on a second driven shaft, which is parallel to the first. The knife and counter knife can be placed transversely to the feed direction of the cardboard. This makes it possible to make cuts in the transverse direction of the feed-through direction. The knife and the counter knife are superimposed. They are placed at a distance from each other, so that when the cutting heads are rotated in the opposite direction, the cardboard can be pulled between them.

Rolling blades as described in the current state of the art are typically used for cutting cardboard. Their reliability is an advantage when using a rolling knife. A disadvantage of these knives, however, is that the speed of cutting is too slow for mass production of cardboard. A low speed of cutting ensures that the throughput of the cardboard is lower than desired. A further disadvantage is the flexibility when used in a machine.

It is an object of the present invention to provide a device and a method for cutting cardboard in a faster, cheaper and / or more reliable manner.

To this end, the invention provides a cutting unit for cutting cardboard, comprising:

- a cutting table with a first cutting edge,

- a knife with a second cutting edge,

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- a first actuator, mounted between the cutting table and the knife, for moving the knife relative to the cutting table in an upward and downward cutting movement, wherein the first and the second cutting edge lie at an angle, so that a contact point can be identified between the first and the second cutting edge during the cutting movement,

- a pressure element, provided to exert a force on the knife, to increase a pressure between the first cutting edge and the second cutting edge at the point of contact.

The cutting unit cuts the cardboard by means of a knife which performs an upward and downward cutting movement. An upward and downward movement is advantageous because it is easily controllable. Another advantage is that one up and down movement can be made very short compared to a rotation movement. The person skilled in the art can also see that with an upward and downward movement the height of the knife can be determined very accurately. The upward and downward cutting movement is performed relative to a cutting table. The cutting table is an element that supports the cardboard while the knife exerts the cutting movement. As a result, the cardboard will not move undesirably during the cutting movement of the knife. The cutting table also serves as a counter knife of the knife that moves relative to the cutting table. This means that the cutting table can exert a counterforce to the force that the knife exerts on the cardboard. The cardboard will therefore not move with the downward movement of the knife. The upward and downward movement of the blade is realized by an actuator. The knife is connected to the cutting table via this actuator. This connection ensures the above-mentioned relative movement of the knife with respect to the cutting table.

The cutting table and the knife have a first and a second cutting edge respectively. This first and second cutting edge define a cutting line where this first and second cutting edge meet. The first and second cutting edges are at an angle, so that each relative position of the knife opposite the cutting table has a cutting point. This point of intersection is identifiable and is formed by the point of contact between the first and the second cutting edge. This means that the knife and the cutting table are positioned or positioned in such a way that an angle is formed between the first and the second cutting edge. The effective cutting of the cardboard is done at the point of contact. A person skilled in the art will realize that this makes cutting more effective. The contact point moves along the cutting edge of the blade as a function of the position of the blade during the up and down movement. The cardboard can be cut along the entire aforementioned cutting line, whereby a cut is made in the cardboard.

A pressure element is positioned such that it exerts a force on the knife. This force increases a pressure between the first and the second cutting edge at the point of contact. In other words, the cutting edge of the knife presses against the cutting edge of the cutting table at the height

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BE2018 / 5233 from the contact point. This is advantageous, since the knife is subject to vibrations and bends during the cutting movement. These vibrations and bends arise because a knife is typically very thin. The vibrations and bends ensure that the contact point between the first and second cutting edges is not always ensured during the cutting movement. However, by increasing the pressure, the vibrations and bends at the point of contact will be reduced. The adverse effects of vibrations and bends become proportionally smaller with increasing pressure between the first and second cutting edges. This increases the reliability of the cutting unit.

The knife preferably comprises a cutting segment, which contains the second cutting edge, and a mounting segment, for mounting with the first actuator. The shape of the mounting segment is adjusted for optimum mounting with the actuator. The confirmation can be done via a holder. This holder holds the knife so that it is not movable relative to the holder. The holder is attached to the actuator, so that the blade is attached to the actuator via the holder. The cutting segment contains the cutting edge of the knife. This means that during the cutting movement the cutting segment makes the cut in the cardboard. The division of the knife into a mounting segment and a cutting segment has the advantage that the mounting of the knife does not form an obstruction for the optimum operation of the cutting unit.

The knife is preferably attached to the first actuator via a hinge element, pivotable along an upward axis. The hinge element serves as a spindle, so that the knife is rotatable. This rotatability has the advantage that the effect of the pressure element is greater than, for example, when the knife is rigidly or immovably mounted relative to the actuator.

The hinge element is preferably mounted at a distance from the pressure element, and provided to provide a counter force against the force, such that the counter force induces a moment of force about the upward axis. The hinge element can be attached to the knife at a distance from the pressure element. This has the effect that the pressure of the pressure element is converted into a moment of force. This moment of force can cause the knife to move about the upward axis. This has the advantage that the effect of the pressure element is greater than with a device that does not use a pressure element and a moment of force.

The first actuator is preferably a linear actuator. By using a linear actuator, the blade movement is linear. This makes the cutting movement easier, which reduces maintenance costs, and the speed of cutting can be increased. A higher speed means that a higher throughput of cardboard is possible.

The cutting unit is preferably part of a device for making blanks, the device comprising a feed, a cutting device and a controller,

- the supply being provided for supplying the cardboard to the cutting device,

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- wherein the cutting device comprises at least one cutting unit according to one of the preceding claims, provided for making a cut in the cardboard, based on input from the controller, and

- wherein the cutting device comprises a drive line for advancing the cardboard in a drive direction.

By making the cutting unit part of a device, the cutting can be further automated. The cardboard is typically supplied via a power train and automatically cut based on the input from the controller. The advantage of this is that the number of cuts can be increased while the accuracy of cutting is better.

The cutting unit is part of a cutting device. This cutting device is part of the device that also contains a controller and a feed. The cutting device thus comprises at least one cutting unit, and the device contains the cutting device. The use of the cutting unit in the device has the advantage that it can perform a simple and easily controllable cutting movement. Due to the simple cutting movement, cutting can take place faster and the device has a lower maintenance cost. Due to the higher speed of the cutting unit, the speed of the machine is also higher. This means that the throughput of the device is increased. This increase is due to the simple cutting movement that the cutting unit makes.

The at least one cutting unit preferably comprises a second actuator, movable in a transverse direction on the drive line, so that a position of the at least one cutting unit can be adjusted in the transverse direction. By adding a second actuator, the cutting unit has an additional direction of movement. This is an advantage because the position or location of the cutting unit relative to the cardboard can thus be adjusted in a transverse direction. The cutting unit can therefore move over the cardboard. This has the advantage that the size of the cut in the cardboard can be selected. Furthermore, adding this second actuator has the advantage that blanks of different sizes can be made. This can happen automatically because the movement in the transverse direction can be controlled by the actuator. Alternatively, the magnitude of the cut made can be determined by precisely controlling the height of the up and down movement. A certain length is cut into the cardboard at each height of the knife. The person skilled in the art can see that the depth of the cut can be determined with knowledge of the angle and the height of the knife. As a result, it is possible to determine in advance up to which height a cut must be made for a certain depth of cut. Furthermore, preferably a combination of the movement in the transverse direction and the height of the cutting movement can be used.

The at least one cutting unit preferably comprises at least two cutting units, which are positioned on either side of the drive line, so that the cardboard can be cut on both sides. The addition of a cutting unit so that it is on either side of the drive line

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BE2018 / 5233 have the advantage that the cardboard can be cut on both sides. This is advantageous because the number of cutting movements required for making the blank is reduced. In this way the device can simultaneously make a cutting movement on either side of the cardboard. This cutting movement on both sides can be done synchronously, so that two cuts can be made simultaneously. The cutting movement on both sides can also be done alternately. This means that no cut is made on either side at the same time.

The at least two cutting units are preferably positioned so that their first cutting edges are on a straight line. Positioning the cutting units in this way makes cutting on the same transverse axis possible. The at least two cutting units can thus make two cuts on the transverse axis. These cuts are in line with each other. This makes it possible, for example, to make two flaps from a blank by one cutting movement of the device. In other words, a flap is made synchronously on both sides of the cardboard. This flap can also be made alternately.

The at least two cutting units are preferably positionable in the transverse direction so that the knives are in contact with each other. Rakelings is here defined as "almost touching". When the at least two cutting units are in close contact, the device is suitable for making a cut over the entire transverse direction. This means that the cardboard can be divided into two different parts. In other words, the cardboard can be cut completely. This is important, for example, when cutting the cardboard for making multiple blanks.

The invention further relates to a method for cutting cardboard by means of a cutting unit, which comprises a cutting table with a first cutting edge, a knife with a second cutting edge, the first cutting edge and the second cutting edge being at an angle, the following steps:

- moving the knife relative to the cutting table in an upward and downward cutting movement by means of a first actuator;

- pressing on the knife by a pressure element, during said cutting movement, to increase a pressure between the first cutting edge and the second cutting edge at the level of a contact point.

The cutting unit cuts the cardboard by means of a knife which performs an upward and downward cutting movement. The method consists in causing the knife to move up and down relative to the cutting table, which serves as a counter knife. A pressure element may press on the knife during this cutting movement. By pressing during the cutting movement, the knife can be pressed against the cutting table. By doing this during the cutting movement, the vibrations and

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BE2018 / 5233 bends can be suppressed. This has the advantages as stated in the description of the cutting unit and / or cutting device.

The method of the cutting device preferably comprises at least two cutting units, which are positioned on either side of the drive line, so that the cardboard can be cut on both sides.

By cutting the cardboard on two sides, the number of required cutting movements can be reduced. The total cutting time required for forming all cuts can also be reduced. This is the case, for example, when cutting a blank. A blank often has to cut a flap on two sides, so that it can be made during one cutting movement.

The at least two cutting units are preferably positionable so that their first cutting edges are on a straight line.

By cutting the cardboard along a straight line, the cutting can be further facilitated. For example, for cutting two flaps along either side of the cardboard. These two flaps are usually in line with each other. This makes it advantageous for the position of the blades to be in line with each other, or on the same straight line. The skilled person will realize that this makes it easier to position the blades properly. Preferably, the at least two cutting units are positionable so that the blades are in contact with each other during the cutting movement, whereby the cardboard divides into two.

When the two knives on both sides of the power train are close, it is possible to divide the cardboard into two pieces. This has the advantage that no additional cutting units have to be added, for cutting the cardboard into two parts.

The invention will now be described in more detail with reference to an exemplary embodiment shown in the drawing.

In the drawing:

Figure 1 shows a side view of a cutting unit according to an embodiment of the invention;

Figure 2 shows a top view of a cutting unit according to an embodiment of the invention;

Figure 3 shows a device with a cutting unit, feed and a controller according to an embodiment of the invention; and, figure 4 shows a plano in top view.

In the drawing, the same reference numeral is assigned to the same or analogous element.

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The cutting unit according to the invention is primarily intended for use in a device for cutting cardboard. Figure 3 shows a preferred embodiment of a device for making blanks. The device is provided for making blanks, which can then be subsequently folded into boxes. The boxes can for example be used for packing and sending online purchases.

The cutting unit comprises a knife 3 and a cutting table 1, as shown in FIG. 1. The knife is preferably of the guillotine type. This means that the knife exerts an upward and downward movement 22, also known as a falling movement. This makes it easy to set up the knife. It is preferably a straight guillotine blade 3. The blade 3 can consist of one or more parts, including, for example, a fastening segment 8 and a cutting segment 7.

The knife 3 is preferably made of a metal, further preferably the knife 3 is made of stainless steel. Alternatively, the knife can also be made of a ceramic material or another hard, sharp material.

The cutting table 1 serves as a counter knife for the knife 3, serving for a proper functioning of the cutting unit. The cutting table is preferably straight along the cutting edge 2, whereby the knife 3 with its cutting edge 4 can slide along the cutting edge of the cutting table 2. For this, the knife is placed at an angle 6 with respect to the cutting table. This angle introduces a point of contact between the cutting edge of the cutting table and the knife (2,4). This point of intersection is identifiable and is formed by the point of contact between the first and the second cutting edge. The contact point is only visible when the cutting edges (2,4) intersect. This always happens with a cutting movement 22. This means that the knife 3 and the cutting table 1 are positioned or positioned such that an angle 6 is formed between the first and the second cutting edge (2,4). The effective cutting of the cardboard is done at the point of contact. Another name for the contact point is the intersection. This effective cutting can be explained with the help of figure 1.

Figure 1 shows the knife 3 in a position above the cutting table 1. As a result, Figure 1 does not yet have a contact point. The knife 3 and the cutting table 1 are too far apart so that the cutting edges (2,4) do not intersect. When the knife 3 from figure 1 is lowered by the actuator 5, a contact point will arise at a certain moment during the cutting movement. In figure 1 this contact point is created on the right side of the knife. Alternatively, in another embodiment of the invention, it may be on the left side of the blade. This can be done, for example, by tilting the knife on the other side. This contact point, or intersection point, moves with every movement 22 of the blade. This means that the position of the contact point moves a certain distance over the cutting edge of the cutting table 2 during the cutting movement 22. In Figure 1, this movement of the contact point is from right to left. This relocation of the

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BE2018 / 5233 is the contact point in function of the position of the knife 3. In the case that the knife 3 is a straight knife 3, this displacement is directly proportional to the position of the knife 3.

The cutting table 1 is preferably flat along an upper side 21, as a result of which the cardboard can move over this flat upper side 21. Furthermore, this upper side is preferably smooth so that the cardboard can move on without appreciable resistance. Alternatively, the cutting table 1 is shaped like a knife with a sharp edge, which is provided at a distance from a sliding surface (not shown). This sliding surface fulfills the function of supporting the cardboard, analogous to the flat top 21 of the cutting table 1 in figure 1. The knife with the sharp edge serves as a counter knife for the knife. The sharp edge of the knife then serves as a cutting edge 2. The knife is operated by an actuator 5. This actuator 5 ensures that the knife 3 can exert an upward and downward cutting movement 22 opposite the cutting table 1. This cutting movement 22 is preferably a linear movement. The actuator can for instance be a pneumatic or an electromechanical actuator. The movement of the actuator 5 is preferably a linear movement, further preferably in the upward and downward direction 22.

Figure 2 shows the pressure element 12 which is provided for exerting a force F on the knife 3. In particular, this force is directed such that a pressure between the first and the second cutting edge 2,4 can be increased. Consequently, the distance 13 between the knife 3 and the cutting table 1 is reduced. Furthermore, figure 2 shows how the pressure element is placed at a distance from the hinge element 9. This pressure is hereby increased by causing the hinge element 9 to exert a counterforce on the force F, whereby a moment of force F 'is induced. This moment of force F 'ensures the contact between the first and the second cutting edge 2,4 at a contact point which coincides with the point of intersection. In particular, because the knife is pushed against the cutting table, it will increase the pressure at the contact point between the cutting table 1 and the knife 3.

The hinge element 9 is hinged along an upward axis 10, so that the knife 3 can be turned so that it is closer to or further from the cutting table 1. In other words: a distance 13 between the knife 3 and the cutting table 1 is adjustable. This is important for a proper functioning of the cutting unit. When the knife 3 makes a downward movement 22 close to the cutting table 1, the cutting table 1 will serve better as a counter knife.

In an alternative embodiment, which is not shown, the pressure element can be designed as a torque spring in the hinge element 9. Furthermore, it can alternatively be designed as a pneumatic cylinder. Further alternatively, the pressure element can be spring.

In use, the knife moves relative to the counter knife, whereby the cardboard is cut at the cutting edge of the cutting table 2. The knife 3 is preferably at an angle 6, so that the cutting edges of the knife and the cutting table 2,4 only touch each other on a minimal surface, this contact surface is related to the point of intersection. The effect of it

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BE2018 / 5233 pressure element 12 relates to this contact surface. Due to the cutting movement 22, the knife 3 undergoes undesired effects such as vibrations and bends. By having the pressure element 12 pressed on the knife 3, this contact surface can be ensured.

Figure 3 schematically shows a cutting device in top view. The cutting device of figure 3 has an input 19, shown on the top of the figure, and an output 20, shown on the bottom of the figure. The cardboard is supplied as a continuous belt at the entrance 19. Blanks 40, as shown in Figure 4, emerge from the cutting device at the location of the outlet 20. The cutting device is provided for segmenting a continuous band of cardboard that enters the cutting device via the entrance 19, each segment being provided to form a blank 40. Furthermore, the cutting device is provided to provide each segment with cuts, for example for forming the side flaps in the blank 40, and to provide creasing. It will be clear to a person skilled in the art that the continuous belt can be supplied via the input 19 in a continuous manner, that is to say that the speed at which the cardboard enters is virtually constant, or in a discontinuous manner, that is to say that the speed at which cardboard enters is not constant. For example, when cardboard is supplied discontinuously, the cardboard can be stopped regularly. These stops of the cardboard are preferably synchronized with one or more cutting units 14. The cutting units 14 can then make an incision in the cardboard while the cardboard is stationary. This makes it possible to give the cutting units 14 a fixed position, viewed in the moving direction 22 of the cutting device. When the cardboard is supplied continuously, the cutting units 14 are preferably placed on a carriage which can cause a cutting unit to move synchronously with the cardboard in the moving direction 2 during the cutting. Using such slides, it is possible to cut the cardboard to a standstill and to make several cuts at different longitudinal positions of the cardboard. Because the relative position of the cutting unit and the cardboard is relevant, combinations of the above will also be possible, and it is possible to work with one or more cutting units.

The cutting device is provided with the following components, considered from entrance 19 to exit 20: longitudinal blades 15, longitudinal groove wheels 16, transverse groove rollers 17 and cutting units 14. It will be apparent to those skilled in the art that the order of these various components can be changed in various ways without adversely affecting the essential operation of the machine. In this case, cutting units 14 can be provided, for example, at the entrance 19, in order to cut the continuous strip of cardboard into segments, whereafter the various segments are further processed individually. The outlet 13 is always placed after a cutting unit 14 which is provided for cutting the continuous strip of cardboard into segments. This is further explained below.

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The longitudinal knives 15 are preferably shaped as disks with the peripheral edge of the disk shaped like a knife for cutting the cardboard. The discs are placed on a shaft that extends across the cutting device. Furthermore, the discs are preferably displaceable in the transverse direction. More preferably, the discs are movable in the transverse direction by means of an actuator and the transverse position of the discs can be adjusted by the controller 18. This makes it possible to cut different segments of the cardboard in different widths. This allows blanks 40 of different widths to be produced one after the other with the cutting device. Alternatively, the longitudinal knives 15 can be placed on different transverse axes.

The longitudinal groove wheels 16, like the longitudinal knives, are preferably placed on a transverse axis. The longitudinal groove wheels 16 are preferably also positionable in the transverse direction via an actuator, the position being controlled by the controller 18. This makes it possible to form the longitudinal grooves in successive segments at different transverse positions. This allows successive blanks to have 40 different folding lines.

Two transverse groove rollers 17 are preferably provided next to each other, viewed in the direction of movement. Further preferably, the transverse groove rollers 17 are formed substantially identically, and are individually controllable by the controller 18. Each transverse groove roll 17 is formed as a cylindrical body with a predetermined diameter. A protrusion is provided on the cylindrical body which extends over substantially the entire length of the cylindrical body. This protrusion is provided for, when the cardboard moves under the groove roller and when the cylindrical body rotates, to make an impression in the cardboard through the protrusion. A counter-pressure element is provided below the creasing rollers 17, for example in the form of a plate. Thereby, the distance between the plate and the cylindrical surface is equal to or greater than a thickness of the cardboard, and the distance between the top of the protuberance on the cylindrical surface and the plate when the protuberance is at its closest position is relative to the plate, smaller than the thickness of the cardboard. For example, the cardboard will be able to move under the creasing roller without being significantly affected by it until the bulge is rotated to realize an impression in the cardboard. The person skilled in the art is familiar with the principle of transverse grooving rolls and therefore they are not described in further detail.

Those skilled in the art will also understand how a transverse groove roller can be controlled to form a transverse groove at a predetermined position in the carton. Because two transverse groove rollers are provided, two transverse grooves can be provided close to each other in the cardboard without the passage of the cardboard through the cutting device having to be delayed. The person skilled in the art will understand that if two transverse grooves must be provided close together in the cardboard, and only one transverse groove roller would be provided, then transit of the cardboard must be stopped

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BE2018 / 5233 to allow one transverse roller to make a complete rotation in order to be able to rotate the bulge again to the cardboard. Two transverse grooving rollers provide a solution for this delay so that the throughput can be high.

The cutting device preferably comprises a plurality of cutting units 14 a, a ', b, b ", c, c". These multiple cutting units 14a, a ', b, b', c, c 'are preferably placed two by two side by side, viewed in the direction of movement. These multiple cutting units 14a, a ', b, b', c, c 'are connected to the controller 18. Thus, a good cooperation of the different cutting units can be guaranteed. The multiple cutting units 14a, a ', b, b', c, c 'can therefore make different cuts in the cardboard almost simultaneously by the multiple cutting units 14a, a', b, b ', c, c' almost simultaneously to perform cutting movement 22. The cardboard can herein advance when the multiple cutting units 14 a, a ', b, b', c, c 'are in a position as shown in figure 1. This position is the position when no cutting movement is performed.

In the context of this description, the median plane of a blank is defined as a plane that is not adjacent to an edge of the blank. Planes are separated from each other in a blank by shivering and / or cuts. Furthermore, in this description, the word fold is understood to mean an angle formed in a plate-shaped material.

Figure 4 shows a blank 40. In Figure 4, the blank 40 is shown in top view. A blank 40 is a piece of plate-shaped material that is formed to form a box. The plate-shaped material is typically a cardboard. Alternatively, a blank 40 can also be made from plastic. Forming a blank 40 for making a box is typically understood to mean cutting out the plate-shaped material and forming creases in the plate-shaped material. Figure 4 shows a blank 40 in which the full lines are cutting lines and the dotted lines are shivers. A groove is a depression in the plate-shaped material that facilitates creasing of the plate-shaped material at the location of the depression. Alternatively, a groove can also be a partial incision, wherein the plate-shaped material is partially cut, i.e. not over its full thickness and / or length, such that a weakening of the plate-shaped material results at the location of the cut. This weakening facilitates the creases of the plate at the location of the cut.

The blank from figure 4 has four central planes A, B, C and D. Each of the four central planes is provided to form a wall of the box. In the configuration of Figure 4, the face B forms the bottom wall of the box, faces A and C form upright walls of the box, and face D forms the top wall of the box. The figure also shows how the length 1, width b and height h of the box results from the dimensions of the blank 40. This will be clear to the skilled person and will not be explained further. Each of the planes A, B, C and D has two

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BE2018 / 5233 side flaps, indicated by A ', B', C 'and D' respectively. These side flaps are provided to form the two side walls of the box. Furthermore, in the present embodiment, a closing flap A "is provided on plane A in the direction of movement 25 or longitudinal direction of the blank 40. This closing flap A "serves to connect plane A with plane D when forming the box. In Figure 4, the closing flap A "is formed as a flap protruding in the longitudinal direction of plane A. Alternatively, closing flap A "can also be provided with corresponding side flaps so that closing flap A" extends over the full width of the blank. The advantage of this is that no pieces of waste have to be removed.

In Figure 4, a wedge-shaped piece of cardboard is cut away between adjacent side flaps. In some cases this is an advantage in folding the side flaps. This embodiment is shown in Figure 4 because it clearly illustrates the side flaps. The method according to the invention also makes it possible to start with a blank 40 in which the adjacent side flaps are separated from each other only by a single cut, and in which no key board has been cut away. In other words, the side flaps in the blank 40 may be formed by a straight cut, in the transverse direction of the blank 40, which starts at an edge of the blank and extends toward a central axis of the blank over a length that is equal on the length of the side flaps. Those skilled in the art will further understand that the side flaps A ', B', C 'and D' can be dimensioned to fully or partially form the side surface. When the side surface is only partially formed, the side surface will typically have an opening centrally so that the box is not completely closed. In some situations this is advantageous. When the side face is fully formed, the side flaps can be contiguous or overlapping. Different combinations of these are possible. The skilled person will understand how a blank 40 can be formed to form a box with predetermined dimensions. Folding the blank 40 itself is not part of the present invention, since the present invention relates in particular to forming a blank 40. However, the invention has arisen in the search for a solution for forming and folding boxes on measure. When applying the invention in a broader context, blanks 40 as shown in Figure 4 will therefore be made to measure for the goods to be packaged. The blank 40 preferably has a structure as shown in figure 4.

On the basis of the above description, it will be understood by those skilled in the art that the invention can be practiced in different ways and on different principles. In addition, the invention is not limited to the embodiments described above. The embodiments described above, as well as the figures, are merely illustrative and serve only to increase the understanding of the invention. The invention will therefore not be limited to the embodiments described herein, but is defined in the claims.

Claims (15)

Conclusions A cutting unit for cutting cardboard, comprising: - a cutting table with a first cutting edge, - a knife with a mounting segment and a cutting segment with a second cutting edge, wherein the mounting segment and the cutting segment are connected via a hinge element such that the cutting segment is hinged relative to the mounting segment - a first actuator, mounted between the cutting table and the mounting segment of the knife, for moving the knife relative to the cutting table in an upward and downward cutting movement, wherein the first and the second cutting edge lie at an angle, so that a contact point is detectable between the first and the second cutting edge during the cutting movement, - a pressure element, provided to exert a force on the knife in a direction substantially away from the first cutting edge, to increase a pressure between the first cutting edge and the second cutting edge at the point of contact. The cutting unit according to claim 1, wherein the second cutting edge and the mounting segment are positioned on opposite sides of the hinge element. The cutting unit according to claim 1 or 2, wherein: the hinge element is hingeable along an upward axis. The cutting unit of claim 3, wherein: the hinge element is mounted at a distance from the pressure element, and the pressure element exerts a force on a part of the knife which is situated on the side of the hinge element that lies opposite the second cutting edge to provide a counter force against the force, such that the counter force induces a moment of force about the upward axis. The cutting unit according to any of the preceding claims, wherein: the first actuator is a linear actuator. 6. Device for making blanks, wherein the device comprises a feed, a cutting device and a controller, - the supply being provided for supplying the cardboard to the cutting device, BE2018 / 5233 - wherein the cutting device comprises at least one cutting unit according to one of the preceding claims, provided for making a cut in the cardboard, based on input from the controller, and wherein the cutting device comprises a drive line for advancing the cardboard in a drive direction. The device of claim 6 wherein: the at least one cutting unit comprises a second actuator, movable in a transverse direction on the drive line, so that a position of the at least one cutting unit in the transverse direction can be adjusted. The device of claim 6, wherein: the at least one cutting unit comprises at least two cutting units, which are positioned on either side of the drive line, so that the cardboard can be cut on both sides. The device of claim 9, wherein: the at least two cutting units are positioned so that their first cutting edges are on a straight line. The device of claim 7, wherein: the at least two cutting units can be positioned in the transverse direction so that the blades are in contact. 11. Method for cutting cardboard, the method comprising the following steps: - provided with a cutting unit according to one of the preceding claims; - moving the knife relative to the cutting table in an upward and downward (linear) cutting movement by means of the first actuator; and - pressing on the knife through the pressure element, during said cutting movement, to increase a pressure between the first cutting edge and the second cutting edge at the level of a contact point. The method of claim 11, wherein the cutting device comprises a drive line and at least one cutting unit, the method further comprising: feeding the cardboard to the cutting device by means of the drive line; positioning the knife by a second actuator in a transverse direction on the drive line, so that a position of the at least one cutting unit in the transverse direction can be adjusted. BE2018 / 5233 A method according to claim 12, wherein the cutting device comprises at least two cutting units, which are positioned on either side of the drive line, so that the cardboard can be cut on both sides. 5 The method of claim 13, wherein the at least two cutting units are positionable so that their first cutting edges are on a straight line. 15. Method as claimed in claim 13 or 14, wherein the at least two cutting units are positionable so that the knives are close to scratch during the cutting movement wherein the cardboard divides into two.